Josephson current source systems and method

ABSTRACT

One embodiment describes a Josephson current source system. The system includes a flux-shuttle loop that is inductively coupled with an AC input signal. The flux-shuttle loop includes a plurality of Josephson junctions spaced about the flux-shuttle loop and being configured, when activated, to sequentially trigger the plurality of Josephson junctions about the flux-shuttle loop in response to the AC input signal to generate a DC output current provided through an output inductor. The system also includes a flux injector that is configured to selectively activate and deactivate the flux-shuttle loop in response to an input signal to control an amplitude of the DC output current.

TECHNICAL FIELD

The present invention relates generally to quantum and classical digital superconducting circuits, and specifically to Josephson current source systems and method.

BACKGROUND

Superconducting digital technology has provided computing and/or communications resources that benefit from unprecedented high speed, low power dissipation, and low operating temperature. Superconducting digital technology has been developed as an alternative to CMOS technology, and typically comprises superconductor based single flux quantum superconducting circuitry, utilizing superconducting Josephson junctions, and can exhibit typical power dissipation of less than 1 nW (nanowatt) per active device at a typical data rate of 20 Gb/s (gigabits/second) or greater, and can operate at temperatures of around 4 Kelvin. Certain superconducting circuits in which Josephson junctions are the active devices can require a DC current bias of the Josephson junctions. Typical systems can provide the DC bias current directly using a bias resistor network, which can result in spurious magnetic fields and heat resulting from high power dissipation. The power budget in such circuits can be dominated by static power consumption, which can be dissipated in the bias resistor network whether or not the active device is switching.

SUMMARY

One embodiment describes a Josephson current source system. The system includes a flux-shuttle loop that includes a plurality of Josephson junctions spaced about the flux-shuttle loop and being configured, when activated, to sequentially trigger the plurality of Josephson junctions about the flux-shuttle loop, in response to an inductively-coupled AC input signal, to generate a DC output current provided through an output inductor. The system also includes a flux injector that is configured to selectively activate and deactivate the flux-shuttle loop to control an amplitude of the DC output current.

Another embodiment includes a method for controlling an amplitude of a DC output current. The method includes providing a first single-flux quantum (SFQ) pulse to a first flux injector to generate a first fluxon element that propagates around at least one flux-shuttle loop via sequential triggering of a plurality of Josephson junctions based on an AC input signal to increase the amplitude of the DC output current in an output inductor. The method also includes providing a first reciprocal SFQ pulse to the first flux injector to generate a first anti-fluxon element that substantially cancels the first fluxon element to maintain the amplitude of the DC output current. The method also includes providing a second SFQ pulse to a second flux injector to generate a second fluxon element that propagates around the at least one flux-shuttle loop via sequential triggering of the plurality of Josephson junctions based on the AC input signal to decrease the amplitude of the DC output current in the output inductor. The method further includes providing a second reciprocal SFQ pulse to the second flux injector to generate a second anti-fluxon element that substantially cancels the second fluxon element to maintain the amplitude of the DC output current.

Another embodiment describes a Josephson current source system. The system includes a flux-shuttle loop that includes a plurality of Josephson junctions spaced about the flux-shuttle loop and being configured, when activated, to sequentially trigger the plurality of Josephson junctions about the flux-shuttle loop in response to an inductively-coupled AC input signal to generate a DC output current provided through an output inductor. The system further includes a flux injector comprising a superconducting quantum interference device (SQUID) having one of a first flux state and a second flux state, the flux injector being configured to change from the first flux state to the second flux state in response to a single-flux quantum (SFQ) pulse to activate the flux-shuttle loop to increase an amplitude of the DC output current. The flux injector can be further configured to change from the second flux state to the first flux state in response to a reciprocal SFQ pulse to deactivate the flux-shuttle loop to maintain the amplitude of the DC output current.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates an example of a superconducting circuit system.

FIG. 2 illustrates an example of a Josephson current source circuit.

FIG. 3 illustrates an example of a timing diagram.

FIG. 4 illustrates an example of a flux injector.

FIG. 5 illustrates another example of a timing diagram.

FIG. 6 illustrates another example of a Josephson current source circuit.

FIG. 7 illustrates an example of a Josephson current source system.

FIG. 8 illustrates another example of a Josephson current source system.

FIG. 9 illustrates an example of a superconducting circuit system.

FIG. 10 illustrates an example of a method for controlling an amplitude of a DC output current.

DETAILED DESCRIPTION

The present invention relates generally to quantum and classical digital superconducting circuits, and specifically to Josephson current source systems and method. The Josephson current source includes a flux-shuttle loop comprising a plurality of stages. Each of the plurality of stages comprises a transformer, at least one Josephson junction, and a storage inductor. The transformer is configured to inductively couple an AC input signal to the flux-shuttle loop, such that the AC input signal provides a bias current in the flux-shuttle loop. The Josephson current source also includes a flux injector configured to selectively activate and deactivate the flux-shuttle loop. For example, the flux injector can be configured to receive a single-flux quantum (SFQ) pulse to activate the flux-shuttle loop and a reciprocal SFQ pulse to deactivate the flux-shuttle loop. Thus, when the flux-shuttle is activated, the Josephson junction(s) in each of the stages triggers to propagate a fluxon (e.g., an SFQ pulse) around the flux-shuttle loop based on the frequency of the AC input signal. As an example, the fluxon can propagate through a given stage at each positive and negative cycle of the AC input signal. The fluxon is provided to the storage inductor of each of the plurality of stages to provide a voltage pulse to an output inductor, such that the output inductor provides a rising DC output current ramp.

As an example, the AC input signal can include an in-phase AC input signal and a quadrature-phase AC input signal, and the flux-shuttle loop can include four stages. A primary winding of the transformers of two of the stages can have an opposite polarity relative to a primary winding of the transformers of the other two of the stages. Therefore, on a positive cycle of each of the in-phase AC input signal and the quadrature-phase AC input signal, the bias current induced in secondary windings of the transformers in two of the stages can be provided in a given direction around the flux-shuttle loop, and on a negative cycle of each of the in-phase AC input signal and the quadrature-phase AC input signal, the bias current induced in secondary windings of the transformers in the other two of the stages can be provided in the same given direction around the flux-shuttle loop. Therefore, the Josephson junction(s) in each of the stages can sequentially trigger at each 90° of the AC input signal to rotate the fluxon around the flux-shuttle loop to provide voltage pulses to the output inductor to generate the rising DC output current.

Based on the selective activation and deactivation of the flux-shuttle loop via the flux injector, the amplitude of the DC output current can be selectively controlled based on propagating fluxon elements around the flux-shuttle loop. As described herein, the term “fluxon element” refers to a fluxon or an anti-fluxon, and the term “anti-fluxon element” refers to the opposite of a respective fluxon element, and thus refers to an anti-fluxon or a fluxon, respectively. As an example, the DC output current can increase during propagation of a fluxon element (e.g., a fluxon) around at least one flux-shuttle loop, and the amplitude of the DC output current can be maintained (e.g., held at a constant amplitude in a zero load condition) in response to deactivation of the at least one flux-shuttle loop based on the reciprocal SFQ pulse received at the flux injector. The maintained amplitude of the DC output current can, for example, be less than a maximum compliance amplitude of the output inductor. Similarly, the DC output current can decrease during propagation of a fluxon element around at least one flux-shuttle loop, and the amplitude of the DC output current can be maintained (e.g., held at a constant amplitude in a zero load condition) in response to deactivation of the at least one flux-shuttle loop based on the reciprocal SFQ pulse received at the flux injector.

For example, two flux injectors can be implemented in a given DC output current source. The flux injectors can both be implemented in a single flux-shuttle loop or can be implemented in two respective flux-shuttle loops, to selectively increase and decrease the amplitude of the DC output current. For example, in a single flux-shuttle loop, a first flux injector can be configured to propagate a first fluxon element (e.g., a fluxon) around the flux-shuttle loop to increase the amplitude of the DC output current and to introduce an anti-fluxon element (e.g., an anti-fluxon) to cease the increase of the amplitude of the DC output current. Similarly, the second flux injector can be configured to propagate a second fluxon element (e.g., an anti-fluxon) around the flux-shuttle loop to decrease the amplitude of the DC output current and can introduce an anti-fluxon element (e.g., a fluxon) to cease the decrease of the amplitude of the DC output current. As another example, two flux-shuttle loops can be coupled to opposite ends of the output inductor, such that a first fluxon element (e.g., a fluxon) propagating around the first flux-shuttle loop can increase the amplitude of the DC output current and an anti-fluxon element (e.g., an anti-fluxon) introduced into the first flux-shuttle loop can cease the increase of the amplitude of the DC output current. Similarly, a second fluxon element (e.g., a fluxon) propagating around the second flux-shuttle loop can decrease the amplitude of the DC output current, and an anti-fluxon element (e.g., an anti-fluxon) introduced into the second flux-shuttle loop can cease the decrease of the amplitude of the DC output current.

FIG. 1 illustrates an example of a superconducting circuit system 10. As an example, the superconducting circuit system 10 can be implemented in any of a variety of classical and quantum computing applications, such as memory or processing systems. The superconducting circuit system 10 includes a device 12 that receives a DC output current, demonstrated in the example of FIG. 1 as a DC output current I_(DC). As an example, the DC output current I_(DC) can be provided as a power signal or as a driver signal to drive the device 12. For example, the device 12 can correspond to a memory driver, such as to provide a read current or a write current to a memory cell.

The superconducting circuit system 10 also includes a Josephson current source 14 that is configured to generate the DC output current I_(DC) in response to a clock signal AC that can correspond to a clock signal associated with the Josephson current source 14. As an example, the clock signal AC can be a sinusoidal waveform having a substantially constant frequency (e.g., approximately 10 GHz) and a low AC current magnitude, such as applicable to reciprocal quantum logic (RQL) superconducting circuits (e.g., approximately 2 mA RMS). The Josephson current source 14 is demonstrated as receiving an input signal RQL_(IN) that can be provided to the Josephson current source 14 to selectively activate and deactivate the operation of the Josephson current source 14 to generate the DC output current I_(DC). For example, the input signal RQL_(IN) can be provided via a reciprocal quantum logic (RQL) circuit. As an example, the input signal RQL_(IN) can be one of a single-flux quantum (SFQ) pulse and a reciprocal SFQ pulse to control an amplitude of the DC output current.

In the example of FIG. 1, the Josephson current source 14 includes a flux-shuttle loop 16. The flux-shuttle loop 16 can include a plurality of stages that are configured to propagate a fluxon around the flux-shuttle loop 16 based on the frequency of the clock signal AC. As described herein, the term “loop” with respect to the flux-shuttle loop 16 describes a substantially continuous loop (e.g., circular) arrangement of the stages of the flux-shuttle loop 16, such that a first stage can be coupled to a last stage. Therefore, the fluxon can substantially continuously propagate around the flux-shuttle loop 16 in response to a first state of the input signal RQL_(IN) (e.g., an SFQ pulse) and can similarly cease propagation around the flux-shuttle loop 16 in response to a second state of the input signal RQL_(IN) (e.g., a reciprocal SFQ pulse). As an example, the second state of the input signal RQL_(IN) can introduce an anti-fluxon into the flux-shuttle loop 16 (e.g., at half a clock cycle out-of-phase of the fluxon), such that the attractive force between the fluxon and the anti-fluxon can interact to substantially annihilate the fluxon. As a result, the amplitude of the DC output current I_(DC) can be maintained at a specific amplitude (e.g., in a zero load condition associated with the device 12).

As an example, the flux-shuttle loop 16 can be arranged with or without shunt resistors. As an example, each of the stages of the flux-shuttle loop 16 can include a transformer, at least one Josephson junction, and a storage inductor. The transformer can be configured to inductively couple the clock signal AC to the flux-shuttle loop 16, such that the clock signal AC provides a bias current in the flux-shuttle loop 16. Thus, in response to the AC bias currents, the Josephson junction(s) in each of the stages of the flux-shuttle loop 16 triggers to propagate a fluxon around the flux-shuttle loop 16 based on the frequency of the clock signal AC. As an example, the fluxon can propagate through a given one of the stages at each positive and negative cycle of the clock signal AC. The fluxon, as it propagates around the flux-shuttle loop 16, can be provided to the storage inductor of each of the stages of the flux-shuttle loop 16 to provide a voltage pulse, such as to an output inductor in the Josephson current source 14 (not shown). Therefore, an increasing DC output current I_(DC) can flow through the output inductor based on the voltage pulses being sequentially provided to the output inductor based on the frequency of the clock signal AC. For example, the voltage pulses can be generated based on the fluxons providing a small voltage (e.g., approximately 2 μV/GHz) to each of the storage inductors, such that the resulting voltage pulses can be integrated in the output inductor to provide the increasing DC output current I_(DC).

In addition, the Josephson current source 14 includes a flux injector 18 that is configured to selectively activate and deactivate the flux-shuttle loop 16 in response to the input signal RQL_(IN). As an example, the flux injector 18 can include a superconducting quantum interference device (SQUID) that is coupled to (e.g., part of) the flux-shuttle loop 16 and has a flux state corresponding to activation or deactivation of the flux-shuttle loop 16, and which can change state in response to the input signal RQL_(IN). For example, in response to the input signal RQL_(IN) being provided as an SFQ pulse, the flux state can reverse to introduce the fluxon into the flux-shuttle loop 16 to increase the amplitude of the DC output current I_(DC). Similarly, in response to the input signal RQL_(IN) being provided as a reciprocal SFQ pulse, the flux state can again reverse to introduce the anti-fluxon into the flux-shuttle loop 16 to maintain the amplitude of the DC output current I_(DC) (e.g., at an amplitude that is less than a maximum compliance amplitude defined by the output inductor). Therefore, the flux injector 18 can be implemented to control the amplitude of the DC output current I_(DC).

The Josephson current source 14 can therefore operate to generate the DC output current I_(DC) in a power efficient manner. As an example, the Josephson current source 14 can generate substantially no heat from static power dissipation, as opposed to typical resistance-based DC current sources. Accordingly, the Josephson current source 14 can operate more efficiently and effectively than typical current sources, particularly in a quantum computing and energy-efficient high-performance computing environments. In addition, because the flux injector 18 can be configured to selectively activate and deactivate the flux-shuttle loop 16, the amplitude of the DC output current I_(DC) can be selectively controlled. Therefore, the amplitude of the DC output current I_(DC) can be maintained at an amplitude that is less than a maximum compliance limit defined by the associated output inductor, and thus the flux-shuttle loop 16 can be deactivated without maximizing the amplitude of the DC output current I_(DC). Accordingly, as described in greater detail herein, the amplitude of the DC output current I_(DC) can be incremented and decremented in a selective manner.

FIG. 2 illustrates an example of a Josephson current source circuit 50. The Josephson current source circuit 50 can correspond to Josephson current source 14 in the superconducting circuit system 10. Therefore, the Josephson current source circuit 50 includes a flux-shuttle loop 52 that includes a plurality of stages, demonstrated in the example of FIG. 2 as a first stage 54, a second stage 56, a third stage 58, and a fourth stage 60. The stages 54, 56, 58, and 60 are sequentially coupled to form a loop arrangement. The Josephson current source circuit 50 is configured to generate a DC output current based on an AC input signal. In the example of FIG. 2, the AC input signal is demonstrated as including an in-phase clock signal AC_(I) and a quadrature-phase clock signal AC_(Q). As an example, the in-phase clock signal AC_(I) and the quadrature-phase clock signal AC_(Q) can collectively correspond to AC quadrature signals that are implemented for RQL circuits. The DC output current is demonstrated as a current I_(DC) that flows through an output inductor L_(OUT).

Each of the stages 54, 56, 58, and 60 are configured substantially similarly with respect to each other. The first stage 54 includes a transformer T₁, a first Josephson junction J₁ _(_) ₁, and a second Josephson junction J₂ _(_) ₁. The second stage 56 includes a transformer T₂, a first Josephson junction J₁ _(_) ₂, and a second Josephson junction J₂ _(_) ₂. The third stage 58 includes a transformer T₃, a first Josephson junction J₁ _(_) ₃, and a second Josephson junction J₂ _(_) ₃. The fourth stage 60 includes a transformer T₄, a first Josephson junction J₁ _(_) ₄, and a second Josephson junction J₂ _(_) ₄. The first and second stages 54 and 56 are interconnected by a flux injector 62, the second and third stages 56 and 58 are interconnected by an inductor L_(X) _(_) ₁, the third and fourth stages 58 and 60 are interconnected by an inductor L_(X) _(_) ₂, and the fourth and first stages 60 and 54 are interconnected by an inductor L_(X) _(_) ₃.

The transformers T₁ and T₃ include a primary winding L₁ _(_) ₁ and L₁ _(_) ₃, respectively, through which the in-phase clock signal AC_(I) flows, and the transformers T₂ and T₄ include a primary winding L₁ _(_) ₂ and L₁ _(_) ₄, respectively, through which the quadrature-phase clock signal AC_(Q) flows. The transformers T₁ and T₃ provide inductive coupling of the in-phase clock signal AC_(I) to the flux-shuttle loop 52, and the transformers T₂ and T₄ provide inductive coupling of the quadrature-phase clock signal AC_(Q) to the flux-shuttle loop 52. Therefore, the first transformer T₁ can generate a bias current I_(B1) via a secondary winding L₂ _(_) ₁ and the third transformer T₃ can generate a bias current I_(B3) via a secondary winding L₂ _(_) ₃ in response to the in-phase clock signal AC_(I). Similarly, the second transformer T₂ can generate a bias current I_(B2) via a secondary winding L₂ _(_) ₂ and the fourth transformer T₄ can generate a bias current I_(B4) via a secondary winding L₂ _(_) ₄ in response to the quadrature-phase clock signal AC_(Q). As an example, the inductance of the inductors L_(X) _(_) ₁, L_(X) _(_) ₂, L_(X) _(_) ₃, and the inductors of the flux injector 62 (as described in greater detail herein), as well as the secondary windings L2_1, L2_2, L2_3, and L2_4, can be selected to have a loop inductance so that a ratio of the Josephson inductance of the Josephson junctions J₁ _(_) ₁, J₂ _(_) ₁, J₁ _(_) ₂, J₂ _(_) ₂, J₁ _(_) ₃, J₂ _(_) ₃, J₁ _(_) ₄, and J₂ _(_) ₄ to that of the loop inductance is greater than one to provide operation of the flux-shuttle loop 52 in the long junction regime. Therefore, the Josephson junctions J₁ _(_) ₁, J₂ _(_) ₁, J₁ _(_) ₂, J₂ _(_) ₂, J₁ _(_) ₃, J₂ _(_) ₃, J₁ _(_) ₄, and J₂ _(_) ₄, can be damped even in the absence of shunt resistors. Alternatively, the Josephson junctions J₁ _(_) ₁, J₂ _(_) ₁, J₁ _(_) ₂, J₂ _(_) ₂, J₁ _(_) ₃, J₂ _(_) ₃, J₁ _(_) ₄, and J₂ _(_) ₄, can include shunt resistors.

As an example, each of the first in-phase clock signal AC_(I) and the quadrature-phase clock signal AC_(Q) can include a positive portion (e.g., in a first half of a respective period) and a negative portion (e.g., in a second half of a respective period). As demonstrated in the example of FIG. 2, the primary winding L₁ _(_) ₃ of the third transformer T₃ has a polarity that is opposite the polarity of the primary winding L₁ _(_) ₁ of the first transformer T₁. Similarly, the primary winding L₁ _(_) ₄ of the fourth transformer T₄ has a polarity that is opposite the polarity of the primary winding L₁ _(_) ₂ of the second transformer T₂. Therefore, the bias current I_(B1) is induced in a first direction via the second winding L₂ _(_) ₁ of the first transformer T₁ during the negative portion of the in-phase clock signal AC_(I). However, because the primary windings L₁ _(_) ₁ and L₁ _(_) ₃ of the first and third transformers T₁ and T₃, respectively, have opposite polarities, the bias current I_(B3) is also induced in the first direction via the second winding L₂ _(_) ₃ of the third transformer T₃ during the positive portion of the in-phase clock signal AC_(I). Similarly, the bias current I_(B2) is induced in the first direction during the negative portion of the quadrature-phase clock signal AC_(Q), and the bias current I_(B4) is also induced in the first direction during the positive portion of the quadrature-phase clock signal AC_(Q). Therefore, as described in greater detail in the example of FIG. 4, the bias currents I_(B1), I_(B2), I_(B3), and I_(B4) are sequentially provided in each of 90° intervals of the AC input signals AC_(I) and AC_(Q). In the example of FIG. 2, the “first direction” is demonstrated as left-to-right from the respective secondary windings L₂ _(_) ₁, L₂ _(_) ₂, L₂ _(_) ₃, and L₂ _(_) ₄.

The flux injector 62 is demonstrated as receiving a bias current I_(BIAS) and an input signal RQL_(IN) that can be provided to the Josephson current source circuit 50 (e.g., from an RQL circuit) to activate the flux-shuttle loop 52, and thus initialize the operation of the Josephson current source circuit 50. As an example, the input signal RQL_(IN) can be an SFQ pulse or a reciprocal SFQ pulse that can activate and deactivate the flux-shuttle loop 52, respectively. As an example, the flux injector 62 can include a SQUID that interconnects the transformers T₁ and T₂ and has a flux state corresponding to activation or deactivation of the flux-shuttle loop 52, and which can change state in response to the input signal RQL_(IN). For example, in response to the input signal RQL_(IN) being provided as the SFQ pulse, the flux state can reverse to introduce a fluxon into the flux-shuttle loop 52 in the direction of the flow of the currents I_(B1), I_(B2), I_(B3), and I_(B4) to activate the flux-shuttle loop 52, and thus to sequentially trigger the Josephson junctions J₁ _(_) ₁, J₂ _(_) ₁, J₁ _(_) ₂, J₂ _(_) ₂, J₁ _(_) ₃, J₂ _(_) ₃, J₁ _(_) ₄, and J₂ _(_) ₄. Similarly, in response to the input signal RQL_(IN) being provided as a reciprocal SFQ pulse, the flux state can again reverse to introduce the anti-fluxon into the flux-shuttle loop 52 (e.g., at half a clock cycle out-of-phase of the fluxon) in the same direction as the fluxon. Therefore, an attractive force between the fluxon and the anti-fluxon can draw the fluxon and anti-fluxon together to annihilate the fluxon, thus deactivating the flux-shuttle loop 52.

The addition of the fluxon and the bias current I_(B2) can be sufficient to exceed a critical current of the Josephson junction J₁ _(_) ₂. For example, during a negative portion of the quadrature-phase clock signal AC_(Q), the bias current I_(B2) and the fluxon resulting from triggering of the Josephson junction J₁ _(_) ₂ can combine to flow through the Josephson junction J₂ _(_) ₂. In response, because the magnitude of the bias current I_(B2) and the fluxon exceed the critical current of the Josephson junction J₂ _(_) ₂, the Josephson junction J₂ _(_) ₂ triggers to propagate the fluxon from the second stage 56 to the third stage 58 through the inductor L_(X) _(_) ₁ to trigger the first Josephson junction J₁ _(_) ₃. During the positive portion of the in-phase clock signal AC_(I), the fluxon can combine with the bias current I_(B3) to trigger the Josephson junction J₂ _(_) ₃. As a result, the Josephson junction J₂ _(_) ₃ propagates the fluxon to the fourth stage 60. The Josephson junctions J₁ and J₂ in each of the stages 54, 56, 58, and 60 can thus continue to sequentially trigger based on the frequency of the in-phase clock signal AC_(I) and the quadrature-phase clock signal AC_(Q). Accordingly, the fluxon is sequentially propagated through each of the stages 54, 56, 58, and 60 at each 90° interval of the AC input signals AC_(I) and AC_(Q).

In response to the fluxon sequentially propagated through the Josephson junction J₂ in each of the stages 54, 56, 58, and 60, a voltage pulse is generated that increments the current in a storage inductor interconnecting the stages 54, 56, 58, and 60. In the example of FIG. 2, a storage inductor L_(S) _(_) ₁ (associated with the flux injector 62) interconnects the first and second stages 54 and 56, a storage inductor L_(s 2) (associated with the inductor L_(X) _(_) ₁) interconnects the second and third stages 56 and 58, a storage inductor L_(S) _(_) ₃ (associated with the inductor L_(X) _(_) ₂) interconnects the third and fourth stages 58 and 60, and a storage inductor L_(S) _(_) ₄ (associated with the inductor L_(X) _(_) ₃) interconnects the fourth and first stages 60 and 54. Thus, in response to the Josephson junction J₂ _(_) ₁ triggering, the fluxon generates a resulting current increment I_(P1) in the storage inductor L_(S) _(_) ₁. In response to the Josephson junction J₂ _(_) ₂ triggering, the fluxon generates a resulting current increment I_(P2) in the storage inductor L_(S) _(_) ₂. In response to the Josephson junction J₂ _(_) ₃ triggering, the fluxon generates a resulting current increment I_(P3) in the storage inductor L_(S) _(_) ₃. In response to the Josephson junction J₂ _(_) ₄ triggering, the fluxon generates a resulting current increment I_(P4) in the storage inductor L_(S) _(_) ₄. Each of the storage inductors L_(S) _(_) ₁, L_(S) _(_) ₂, L_(S) _(_) ₃, and L_(S) _(_) ₄ are coupled to the output inductor L_(OUT). As a result, the output inductor L_(OUT) integrates each of the current increments I_(P1), I_(P2), I_(P3), and I_(P4) to provide an increasing amplitude of the DC output current I_(DC). As a result, the DC output current I_(DC) can be provided to a device (e.g., the device 12 in the example of FIG. 1) based on the in-phase clock signal AC_(I) and the quadrature-phase clock signal AC_(Q), and the number of times the fluxon has propagated around the flux-shuttle loop 52 before the flux-shuttle loop 52 is deactivated.

FIG. 3 illustrates an example of a timing diagram 100. The timing diagram 100 includes the in-phase clock signal AC_(I) and the quadrature-phase clock signal AC_(Q), as indicated at the legend 102, as a function of time. The in-phase clock signal AC_(I) and the quadrature-phase clock signal AC_(Q) are each demonstrated as sinusoidal signals having magnitudes centered about zero. The in-phase clock signal AC_(I) and the quadrature-phase clock signal AC_(Q) in the example of FIG. 3 can correspond to the in-phase clock signal AC_(I) and the quadrature-phase clock signal AC_(Q) in the example of FIG. 2. Therefore, reference is to be made to the example of FIG. 2 in the following description of the example of FIG. 3.

The flux-shuttle loop 52 can be activated via the flux injector 62, as described in greater detail herein. Upon activation, at a time t₀, a negative portion of the in-phase clock signal AC_(I) begins, with a positive peak of the in-phase clock signal AC_(I) occurring at a time t₁. Therefore, the in-phase clock signal AC_(I) begins to induce the bias current I_(B1) via the secondary winding L₂ _(_) ₁ in the first direction based on the inductive coupling with the primary winding L₁ _(_) ₁. At a time just subsequent to the time t₁ (e.g., based on the inductance of the transformer T₁), the magnitude of the bias current I_(B1), combined with the fluxon provided by the Josephson junction J₁ _(_) ₁, exceeds the critical current of the Josephson junction J₂ _(_) ₁ having previously triggered, and therefore becomes sufficient to trigger the Josephson junction J₂ _(_) ₁. As a result, the Josephson junction J₂ _(_) ₁ propagates the fluxon, which generates the current increment I_(P1) in the storage inductor L_(S) _(_) ₁ via the flux injector 62, as described in greater detail herein, that is integrated by the output inductor L_(OUT) to increase the amplitude of the DC output current I_(DC). The fluxon then propagates to the second stage to trigger the Josephson junction J₁ _(_) ₂.

Also, at the time t₁, a negative portion of the quadrature-phase clock signal AC_(Q) begins, with a positive peak of the quadrature-phase clock signal AC_(Q) occurring at a time t₂. Therefore, the quadrature-phase clock signal AC_(Q) begins to induce the bias current I_(B2) via the secondary winding L₂ _(_) ₂ in the first direction based on the inductive coupling with the primary winding L₁ _(_) ₂. At a time just subsequent to the time t₂ (e.g., based on the inductance of the transformer T₂), the magnitude of the bias current I_(B2), combined with the fluxon provided by the Josephson junction J₁ _(_) ₂ exceeds the critical current of the Josephson junction J₂ _(_) ₂, and therefore becomes sufficient to trigger the Josephson junction J₂ _(_) ₂. As a result, the Josephson junction J₂ _(_) ₂ propagates the fluxon, which generates the current increment I_(P2) in the storage inductor L_(S) _(_) ₂ that is integrated by the output inductor L_(OUT) to increase the amplitude of the DC output current I_(DC) and propagates to the third stage to trigger the Josephson junction J₁ _(_) ₃.

Also, at the time t₂, a positive portion of the in-phase clock signal AC_(I) begins, with a negative peak of the in-phase clock signal AC_(I) occurring at a time t₃. Therefore, the in-phase clock signal AC_(I) begins to induce the bias current I_(B3) via the secondary winding L₂ _(_) ₃ in the first direction based on the inductive coupling with the primary winding L₁ _(_) ₃ (e.g., opposite the polarity of the primary winding L₁ _(_) ₁). At a time just subsequent to the time t₃ (e.g., based on the inductance of the transformer T₃), the magnitude of the bias current I_(B3), combined with the fluxon propagated by the Josephson junction J₁ _(_) ₃, exceeds the critical current of the Josephson junction J₂ _(_) ₃, and therefore becomes sufficient to trigger the Josephson junction J₂ _(_) ₃. As a result, the Josephson junction J₂ _(_) ₃ propagates the fluxon, which generates the current increment I_(P3) in the storage inductor L_(S) _(_) ₃ that is integrated by the output inductor L_(OUT) to increase the amplitude of the DC output current I_(DC) and propagates to the fourth stage to trigger the Josephson junction J₁ _(_) ₄.

Also, at the time t₃, a positive portion of the quadrature-phase clock signal AC_(Q) begins, with a negative peak of the quadrature-phase clock signal AC_(Q) occurring at a time t₄. Therefore, the quadrature-phase clock signal AC_(Q) begins to induce the bias current I_(B4) via the secondary winding L₂ _(_) ₄ in the first direction based on the inductive coupling with the primary winding L₁ _(_) ₄ (e.g., opposite the polarity of the primary winding L₁ _(_) ₂). At a time just subsequent to the time t₄ (e.g., based on the inductance of the transformer T₄), the magnitude of the bias current I_(B4), combined with the fluxon propagated by the Josephson junction J₁ _(_) ₄, exceeds the critical current of the Josephson junction J₂ _(_) ₄, and therefore becomes sufficient to trigger the Josephson junction J₂ _(_) ₄. As a result, the Josephson junction J₂ _(_) ₄ propagates the fluxon, which generates the current increment I_(N) in the storage inductor L_(S) _(_) ₄ that is integrated by the output inductor L_(OUT) to increase the amplitude of the DC output current I_(DC) and propagates to the first stage to trigger the Josephson junction J₁ _(_) ₁.

Also, at the time t₄, a negative portion of the in-phase clock signal AC_(I) begins. Therefore, the process of converting the in-phase clock signal AC_(I) and the quadrature-phase clock signal AC_(Q) repeats, such that the time t₄ is equivalent to the time t₀, as described previously. Accordingly, the Josephson junctions J₁ _(_) ₁, J₂ _(_) ₁, J₁ _(_) ₂, J₂ _(_) ₂, J₁ _(_) ₃, J₂ _(_) ₃, J₁ _(_) ₄, and J₂ _(_) ₄ can sequentially trigger when the flux-shuttle loop 52 is activated via the flux injector 62 to propagate the fluxon around the flux-shuttle loop 52 to continuously provide the current increments I_(P1), I_(P2), I_(P3), and I_(P4) in response to the triggering of the J₂ _(_) ₁, J₂ _(_) ₂, J₂ _(_) ₃, and J₂ _(_) ₄, respectively, to the output inductor L_(OUT) based on the frequency of the in-phase clock signal AC_(I) and the quadrature-phase clock signal AC_(Q). As a result, the output inductor L_(OUT) can integrate the current increments I_(P1), I_(P2), I_(P3), and I_(P4) to increase the amplitude of the DC output current I_(DC).

FIG. 4 illustrates an example of a flux injector 150. The flux injector 150 is configured to generate a fluxon and an anti-fluxon in response to the input signal RQL_(IN) to activate and deactivate, respectively, an associated flux-shuttle loop. The flux injector 150 can correspond to the flux injector 18 in the example of FIG. 1 and/or the flux injector 62 in the example of FIG. 2. Therefore, reference is to be made to the example of FIGS. 1-3 in the following description of the example of FIG. 4.

The flux injector 150 receives the bias current I_(BIAS) and the input signal RQL_(IN), which can correspond to one of an SFQ pulse and a reciprocal SFQ pulse. The bias current I_(BIAS) is provided through an inductor L_(TF) _(_) ₁ that can correspond to a primary winding of a transformer T_(F). The inductor L_(TF) _(_) ₁ can be magnetically coupled to an inductor L_(TF) _(_) ₂ and an inductor L_(TF) _(_) ₃ corresponding to respective secondary windings of the transformer T_(F). Therefore, the bias current I_(BIAS) is induced to flow through the inductors L_(TF) _(_) ₂ and L_(TF) _(_) ₃. The flux injector 150 includes a SQUID 152 that includes the inductor L_(TF) _(_) ₃ and a Josephson junction J_(F). The flux injector 150 also includes an inductor L_(F) _(_) ₁ and L_(F) _(_) ₂ arranged on opposite sides of the SQUID 152 and through which the current I_(B1)flows. Therefore, the SQUID 152 is coupled to and forms a portion of the flux-shuttle loop 52 (e.g., between the transformers T₁ and T₂, as well as the Josephson junctions J₂ _(_) ₁ and J₁ _(_) ₂). As described herein, the SQUID 152 has a flux state ±Φ₀/2 corresponding to a flux direction (e.g., clockwise or counterclockwise) of a flux Φ₀/2. Thus, the SQUID 152 has a first flux state +Φ₀/2 and a second flux state −Φ₀/2 that correspond to respective opposite flux directions of the flux Φ₀/2. The flux state of the SQUID 152 corresponds to activation and deactivation of the flux-shuttle loop 52.

The input signal RQI_(IN) is provided through a first input inductor L_(IN1) to a second input inductor L_(IN2) that is coupled to the inductor L_(TF) _(_) ₂ of the transformer T_(F). In the example of FIG. 4, the first and second input inductors L_(IN1) and L_(IN2) being separated by an input Josephson junction J. As an example, the SQUID 152 can have an initial flux state of +Φ₀/2 corresponding to a deactivated state of the flux-shuttle loop 52. Thus, in response to the input signal RQL_(IN) being provided as an SFQ pulse, the SFQ pulse is provided through the first input inductor L_(IN1) to trigger the input Josephson junction J_(IN) to set a superconducting phase of the Josephson junction J_(IN) to a first superconducting phase. The input Josephson junction J_(IN) then propagates the SFQ pulse through the second input inductor L_(IN2) and through the inductor L_(TF) _(_) ₂. The SFQ pulse is thus induced into the inductor L_(TF) _(_) ₃, and in combination with the bias current I_(BIAS) that is likewise induced into the inductor L_(TF) _(_) ₃, triggers the Josephson junction J_(F). As a result, the flux state of the SQUID 152 switches from +Φ₀/2 to −Φ₀/2, and a fluxon (e.g., SFQ pulse) is emitted from the Josephson junction J_(F) to propagate through the inductor L_(F) _(_) ₂ and around the flux-shuttle loop 52, as described previously in the example of FIG. 3. Therefore, the input signal RQL_(IN) provided as an SFQ pulse can activate the flux-shuttle loop 52 to increase the amplitude of the DC output current I_(DC) in the output inductor L_(OUT).

The input signal RQL_(IN) can also be provided as a reciprocal SFQ pulse to deactivate the flux-shuttle loop 52. As an example, in response to the input signal RQL_(IN) being provided as a reciprocal SFQ pulse (e.g., at half a clock cycle out-of-phase of the fluxon propagating around the flux-shuttle loop 52), the reciprocal SFQ pulse is provided through the first input inductor L_(IN1) to “untrigger” the input Josephson junction J_(IN), and thus set the superconducting phase of the Josephson junction J_(IN) to a second superconducting phase (e.g., an initial superconducting phase). The input Josephson junction J_(IN) then propagates the reciprocal SFQ pulse through the second input inductor L_(IN2) and through the inductor L_(TF) _(_) ₂. The reciprocal SFQ pulse is thus induced into the inductor L_(TF) _(_) ₃, and in combination with the bias current I_(BIAS) that is likewise induced into the inductor L_(TF) _(_) ₃, “untriggers” the Josephson junction J_(F), similar to as described regarding the input Josephson junction J_(IN). As a result, the flux state of the SQUID 152 switches from −Φ₀/2 to +Φ₀/2, and an anti-fluxon (e.g., a reciprocal SFQ pulse) is emitted from the Josephson junction J_(F) to propagate through the inductor L_(F) _(_) ₂ and around the flux-shuttle loop 52, similar to as described previously regarding the fluxon. The attractive force between the fluxon and the anti-fluxon that now both exist in the flux-shuttle loop 52 can be sufficient to overcome a driving force provided by the AC signals AC_(I) and AC_(Q), thus resulting in combination of the fluxon and anti-fluxon to annihilate the fluxon substantially instantaneously. Therefore, the current increments I_(P1), I_(P2), I_(P3), and I_(P4) cease to be provided through the respective storage inductors L_(S) _(_) ₁, L_(S) _(_) ₂, L_(S) _(_) ₃, and L_(S) _(_) ₄, and thus the amplitude of the DC output current I_(DC) is maintained at a current amplitude (e.g., absent a load of the device 12). Accordingly, the input signal RQL_(IN) provided as a reciprocal SFQ pulse can deactivate the flux-shuttle loop 52 to maintain the amplitude of the DC output current I_(DC) in the output inductor L_(OUT).

FIG. 5 illustrates another example of a timing diagram 200. The timing diagram 200 demonstrates the in-phase clock signal AC_(I), the input signal RQL_(IN), the flux state ±Φ₀/2 of the SQUID 152, and the DC output current I_(DC) demonstrated as having a varying amplitude, that are all plotted as a function of time. In the following description of the example of FIG. 5, reference is to be made to the examples of FIGS. 1-4.

In the example of FIG. 5, the SQUID 152 has an initial flux state of +Φ₀/2 (not shown) that corresponds to deactivation of the flux-shuttle loop 52. Therefore, the DC output current I_(DC) is maintained at a substantially constant amplitude (e.g., absent a load condition of the device 12). At a time t₀, demonstrated as occurring at a peak of the in-phase clock signal AC_(I), the input signal RQL_(IN) is provided as an SFQ pulse. While the time t₀ is demonstrated at a peak of the in-phase clock signal AC_(I), it is to be understood that the time t₀ can occur at any other part of the period of the in-phase clock signal AC_(I) (e.g., at a zero-crossing). In response, the SFQ pulse triggers the input Josephson junction J_(IN) to propagate the SFQ pulse through the second input inductor L_(IN2) and through the inductor L_(TF) _(_) ₂. As a result, the Josephson junction J_(F) triggers to switch the flux state of the SQUID 152 switch from +Φ₀/2 to −Φ₀/2, demonstrated diagrammatically at the time t₀ . Therefore, a fluxon (e.g., SFQ pulse) is emitted from the Josephson junction J_(F) to propagate through the inductor L_(F) _(_) ₂ and around the flux-shuttle loop 52, as described previously in the example of FIG. 3. Accordingly, beginning at the time t₀, the flux-shuttle loop 52 is activated to increase the amplitude of the DC output current I_(DC) in the output inductor L_(OUT) based on the current increments I_(P1), I_(P2), I_(P3), and I_(P4) being sequentially provided through the respective storage inductors L_(S) _(_) ₁, L_(S) _(_) ₂, L_(S) _(_) ₃, and L_(S) _(_) ₄ in response to the sequential _(and 2 4). triggering of the Josephson junctions J₁ _(_) ₁, J₂ _(_) ₁, J₁ _(_) ₂, J₂ _(_) ₂, J₁ _(_) ₃, J₂ _(_) ₃, J₁ _(_) ₄,

At a time t₁, the input signal RQL_(IN) is provided as a reciprocal SFQ pulse. As an example, and as described in greater detail herein, a counter (not shown) can be configured to count a number of periods of the in-phase clock signal AC_(I) to increase the DC output current I_(DC) by a predetermined amplitude based on the predetermined number of current increments I_(P1), I_(P2), I_(P3), and I_(P4). In response, the reciprocal SFQ pulse triggers the input Josephson junction J_(IN) to propagate the reciprocal SFQ pulse through the second input inductor L_(IN2) and through the inductor L_(TF) _(_) ₂. As a result, the Josephson junction J_(F) untriggers to switch the flux state of the SQUID 152 switch from −Φ₀/2 to +Φ₀/2, demonstrated diagrammatically at the time t₁. Therefore, an anti-fluxon (e.g., a reciprocal SFQ pulse) is emitted from the Josephson junction J_(F) to propagate through the inductor L_(F) _(_) ₂ and around the flux-shuttle loop 52, as described previously in the example of FIG. 3. The input signal RQL_(IN) is demonstrated in the example of FIG. 5 as providing the reciprocal SFQ pulse, and thus introducing the anti-fluxon, at a trough of the in-phase clock signal AC_(I), thus a half of a clock-cycle out-of-phase with respect to the fluxon. The attractive force between the fluxon and the anti-fluxon results in a substantially instantaneous combination of the fluxon and anti-fluxon to annihilate the fluxon. Therefore, beginning at the time t₁, the flux-shuttle loop 52 is deactivated to cease the current increments I_(P1), I_(P2), I_(P3), and I_(P4), and thus to maintain the constant amplitude of the DC output current I_(DC) (e.g., absent a load of the device 12).

At a time t₂, demonstrated again as occurring at a peak of the in-phase clock signal AC_(I) (e.g., consistent with the time t₀), the input signal RQL_(IN) is provided as an SFQ pulse. In response, the SFQ pulse triggers the input Josephson junction J_(IN) to propagate the SFQ pulse through the second input inductor L_(IN2) and through the inductor L_(TF) _(_) ₂. As a result, the Josephson junction J_(F) triggers to switch the flux state of the SQUID 152 switch from +Φ₀/2 to −Φ₀/2. Therefore, a fluxon is emitted from the Josephson junction J_(F) to propagate through the inductor L_(F 2) and around the flux-shuttle loop 52, as described previously in the example of FIG. 3. Accordingly, beginning at the time t₂, the flux-shuttle loop 52 is activated to once again increase the amplitude of the DC output current I_(DC) in the output inductor L_(OUT) based on the current pulses I_(P1), I_(P2), I_(P3), and I_(P4) being sequentially provided through the respective storage inductors L_(S) _(_) ₁, L_(S) _(_) ₂, L_(S) _(_) ₃, and L_(S) _(_) ₄ in response to the sequential triggering of the Josephson junctions J₁ _(_) ₁, J₂ _(_) ₁, J₁ _(_) ₂, J₂ _(_) ₂, J₁ _(_) ₃, J₂ _(_) ₃, J₁ _(_) _(4,) and J₂ _(_) ₄. As an example, the flux-shuttle loop 52 can be periodically activated to restore the amplitude of the DC output current I_(DC), such as in response to consumption of the DC output current I_(DC) by the device 12.

It is to be understood that the Josephson current source circuit 50 is not intended to be limited to the example of FIG. 2, the flux injector 150 is not intended to be limited to the example of FIG. 4, and the operation of the Josephson current source circuit 50 is not intended to be limited to the examples of FIGS. 3 and 5. As an example, the AC input signal is not limited to being implemented as the in-phase clock signal AC_(I) and the quadrature-phase clock signal AC_(Q), but could instead be a single sinusoidal signal. As another example, the flux-shuttle loop 52 could include more or less than the four stages 54, 56, 58, and 60, such as any multiple of two stages to accommodate positive and negative portions of the AC input signal. Additionally, while the example of FIG. 2 demonstrates the in-phase and quadrature-phase AC input signals AC_(I) and AC_(Q) provided in opposite respective polarities to sequentially provide the bias currents I_(B1), I_(B2), I_(B3), and I_(B4) at each of 90° intervals, other arrangements of AC input signals can be implemented to provide the bias currents I_(B1), I_(B2), I_(B3), and I_(B4) at each of 90° intervals. For example, the Josephson current source circuit 50 can implement four separate AC input signals that are each 90° out of phase of each other, with the transformers T₁ through T₄ all having the same polarity. Furthermore, other types of AC signals can be implemented for providing the DC output current I_(DC), such as square wave signals and/or signals having separate frequencies with respect to each other. As yet another example, the stages 54, 56, 58, and 60 are not limited to the arrangement provided in the example of FIG. 2, but could instead have a different physical arrangement with respect to the Josephson junctions J₁ and J₂, inductors Lx, transformers T₁ through T₄, and/or storage inductors L_(S). Furthermore, the flux injector 150 can be configured in a variety of different ways to inject the fluxon and anti-fluxon into the flux-shuttle loop 52 to selectively activate and deactivate the flux-shuttle loop 52, respectively. Accordingly, the Josephson current source circuit 50 can be configured in a variety of ways.

FIG. 6 illustrates an example of a Josephson current source circuit 250. The Josephson current source circuit 250 can correspond to the Josephson current source 14 in the superconducting circuit system 10. Therefore, the Josephson current source circuit 250 includes a flux-shuttle loop 252 that includes a plurality of stages, similar to as described previously regarding the example of FIG. 2. In the example of FIG. 6, the stages are demonstrated as a first stage 254, a second stage 256, a third stage 258, and a fourth stage 260 that are sequentially coupled to form a loop arrangement. The Josephson current source circuit 250 is configured to generate the DC output current I_(DC) through an output inductor L_(OUT) based on an in-phase clock signal AC_(I) and a quadrature-phase clock signal AC_(Q).

Each of the stages 254, 256, 258, and 260 are configured substantially similarly with respect to each other and with the stages 54, 56, 58, and 60 in the Josephson current source circuit 50 in the example of FIG. 2. Therefore, the circuit components in the Josephson current source circuit 250 are demonstrated as having the same label designations as the circuit components in the Josephson current source circuit 50 in the example of FIG. 2. However, as opposed to the Josephson current source circuit 50 in the example of FIG. 2, the Josephson current source circuit 250 includes a first flux injector 262 and a second flux injector 264. The first and second stages 254 and 256 are interconnected by the first flux injector 262, the second and third stages 256 and 258 are interconnected by the inductor L_(X) _(_) ₁, the third and fourth stages 258 and 260 are interconnected by the second flux injector 264, and the fourth and first stages 260 and 254 are interconnected by the inductor L_(X) _(_) ₃. As described herein, based on the operation of the first and second flux injectors 262 and 264, the Josephson current source circuit 250 can operate as a bipolar Josephson current source to selectively increase and decrease the amplitude of the DC output current I_(DC).

Each of the first and second flux injectors 262 and 264 can be configured substantially similar to the flux injector 150 in the example of FIG. 4, and are each demonstrated as receiving the bias current I_(BIAS). The first flux injector 262 receives an input signal RQL_(IN1) and the second flux injector 264 receives an input signal RQL_(IN2). The input signals RQL_(IN1) and RQL_(IN2) can each be provided to selectively activate and deactivate the flux-shuttle loop 252. As an example, the input signals RQL_(IN1) and RQL_(IN2) can each be provided as an SFQ pulse or a reciprocal SFQ pulse that can activate and deactivate the flux-shuttle loop 252, respectively. However, the flux injector 264 can be arranged to have an initial flux state of an associated SQUID (e.g., the SQUID 152) that is opposite the flux state of the associated SQUID of the flux injector 262.

Therefore, in response to the input signal RQL_(IN1) being provided as the SFQ pulse, the flux state of the first flux injector 262 can reverse to introduce the fluxon into the flux-shuttle loop 252 to activate the flux-shuttle loop 252 to increase the amplitude of the DC output current I_(DC). Similarly, in response to the input signal RQL_(IN1) being provided as a reciprocal SFQ pulse, the flux state can again reverse to introduce the anti-fluxon into the flux-shuttle loop 252 in the same direction as the fluxon to deactivate the flux-shuttle loop to maintain the amplitude of the DC output current I_(DC). However, based on the reverse configuration of the second flux injector 264 relative to the first flux injector 262, the second flux injector 264 can be configured to activate the flux-shuttle loop 252 to decrease the amplitude of the DC output current I_(DC). For example, in response to the input signal RQL_(IN2) being provided as the SFQ pulse while the flux-shuttle loop 252 is deactivated, the flux state of the second flux injector 264 can reverse (e.g., from the −Φ₀/2 flux state to the +Φ₀/2 flux state) to introduce the anti-fluxon into the flux-shuttle loop 252 to activate the flux-shuttle loop 252 to decrease the amplitude of the DC output current I_(DC). Similarly, in response to the input signal RQL_(IN2) being provided as a reciprocal SFQ pulse (e.g., half a clock cycle out-of-phase of the anti-fluxon), the flux state can again reverse (e.g., from the +Φ₀/2 flux state to the −Φ₀/2 flux state) to introduce the fluxon into the flux-shuttle loop 252 in the same direction as the anti-fluxon, such that the attractive force between the fluxon and anti-fluxon cause the fluxon and anti-fluxon to annihilate each other to deactivate the flux-shuttle loop to maintain the amplitude of the DC output current I_(DC).

FIG. 7 illustrates an example of a Josephson current source system 300. As an example, the superconducting circuit system 300 can be implemented in any of a variety of quantum or classical computing applications, such as memory or processing systems. The superconducting circuit system 300 is configured to generate a DC output current, demonstrated in the example of FIG. 7 as a DC output current I_(DC) that is provided via an output inductor L_(OUT). As an example, the DC output current I_(DC) can be provided as a power signal or as a driver signal, such as to drive a device (e.g., the device 12), such as based on an inductive coupling to the output inductor L_(OUT).

The Josephson current source system 300 includes a Josephson current source 302 that is configured to generate the DC output current I_(DC) in response to a clock signal AC that can correspond to a clock signal associated with the Josephson current source system 300. As an example, the clock signal AC can be a sinusoidal waveform having a substantially constant frequency (e.g., approximately 10 GHz) and a low AC current magnitude, such as applicable to RQL superconducting circuits. The Josephson current source 302 includes a flux-shuttle loop 304, a first flux injector 306, and a second flux injector 308. Therefore, the Josephson current source 302 can be configured substantially similar to the Josephson current source 250 in the example of FIG. 6. Accordingly, the Josephson current source 302 can be implemented to control the amplitude of the DC output current I_(DC) by selectively increasing and decreasing the amplitude of the DC output current I_(DC), similar to as described previously in the example of FIG. 6.

In the example of FIG. 7, the Josephson current source system 300 also includes a controller 310 that is configured to generate a first input signal RQL_(IN1)and a second input signal RQL_(IN2) to selectively activate and deactivate the flux-shuttle loop 304 to control the amplitude of the DC output current I_(DC). The controller 310 includes a current register 312 configured to receive a digital signal DC having a value corresponding to a desired amplitude of the DC output current I_(DC). The current register 312 can thus store the value of the digital signal DC. As an example, the current register 312 can be configured to identify a difference between the present amplitude of the DC output current I_(DC) and the desired amplitude indicated by the digital signal DC, such that the current register 312 can be configured to identify whether the amplitude of the DC output current I_(DC) is required to increase or decrease to become equal to the value of the digital signal DC. The current register 312 can thus provide a difference signal DIFF to a counter 314, with the difference signal DIFF corresponding to a difference between the present amplitude of the DC output current I_(DC) and the desired amplitude indicated by the digital signal DC. Additionally, the current register 312 can provide a switch signal SW to a switch 316 that is configured to select between a first RQL latch 318 and a second RQL latch 320 that are configured to generate the first input signal RQL_(IN1)and the second input signal RQL_(IN2), respectively.

Thus, the current register 312 can be configured to enable the switch 316 via the switch signal SW to selectively activate the flux-shuttle loop 304 of the Josephson current source 302 to increase or decrease the DC output current I_(DC), similar to as described previously regarding the Josephson current source 252 in the example of FIG. 2. For example, via the switch signal SW, the switch 316 can enable the first RQL latch 318 to provide the first input signal RQL_(IN1) as an SFQ pulse to activate the flux-shuttle loop 304 via the first flux injector 306 to increase the DC output current I_(DC). The switch 316 can also enable the first RQL latch 318 to provide the first input signal RQL_(IN1)as a reciprocal SFQ pulse to deactivate the flux-shuttle loop 304 via the first flux injector 306 to maintain the DC output current I_(DC) at a quiescent amplitude via the switch signal SW. Similarly, via the switch signal SW, the switch 316 can enable the second RQL latch 320 to provide the second input signal RQL_(IN2) as a SFQ pulse to activate the flux-shuttle loop 304 via the second flux injector 308 to decrease the DC output current I_(DC). The switch 316 can also enable the second RQL latch 320 to provide the second input signal RQL_(IN2)as a reciprocal SFQ pulse to deactivate the flux-shuttle loop 304 via the second flux injector 308 to maintain the DC output current I_(DC) at a quiescent amplitude via the switch signal SW.

The counter 314 can be configured to count clock cycles of the clock signal AC and to activate the first and second RQL latches 318 and 320 to control the increase and decrease of the amplitude of the DC output current I_(DC) based on the difference signal DIFF. In the example of FIG. 7, the counter 314 is configured to provide a trigger signal TRG to the switch 316 to activate the first and second RQL latches 318 and 320 to provide the respective first and second input signals RQL_(IN1) and RQL_(IN2) at the appropriate times based on counting cycles of the clock signal AC and based on predetermined amplitude of the current increments provided to or from the output inductor L_(OUT) at each clock cycle of the clock signal AC. Therefore, the counter 314 can control the timing of initiating the SFQ pulses and reciprocal SFQ pulses provided via the first and second input signals RQL_(IN1) and RQL_(IN2) to selectively activate and deactivate the flux-shuttle loop 304 to set the amplitude of the DC output current I_(DC) to be approximately equal to the value of the digital signal DC based on the difference signal DIFF.

Accordingly, the Josephson current source circuit 250 and the Josephson current source system 300 respectively demonstrate programmable current sources that allow full amplitude control of the DC output current I_(DC) by providing capability of both increasing and decreasing the amplitude of the DC output current I_(DC) using a single flux-shuttle loop (e.g., the flux shuttle loops 252 and 304) by selectively providing a fluxon to the flux-shuttle loops 252 and 304 to increase the amplitude of the DC output current I_(DC) and an anti-fluxon to the flux-shuttle loops 252 and 304 to decrease the amplitude of the DC output current I_(DC). As described in greater detail herein, a Josephson current source system can implement separate respective flux-shuttle loops to implement full amplitude control of the DC output current I_(DC), such as to alleviate potential cross-talk between the separate flux injectors (e.g., the flux injectors 262 and 264).

FIG. 8 illustrates an example of a Josephson current source system 350. As an example, the superconducting circuit system 350 can be implemented in any of a variety of quantum and classical computing applications, such as memory or processing systems. The superconducting circuit system 350 is configured to generate a DC output current, demonstrated in the example of FIG. 8 as a DC output current I_(DC) that is provided via an output inductor L_(OUT). As an example, the DC output current I_(DC) can be provided as a power signal or as a driver signal, such as to drive a device (e.g., the device 12), such as based on an inductive coupling to the output inductor L_(OUT).

The Josephson current source system 350 includes a first Josephson current source 352 and a second Josephson current source 354 that are each coupled on opposite sides of the output inductor L_(OUT). Thus, the first and second Josephson current sources 352 and 354 are configured to generate the DC output current I_(DC) in response to a clock signal AC that can correspond to a clock signal associated with the Josephson current source system 350. As an example, the clock signal AC can be a sinusoidal waveform having a substantially constant frequency (e.g., approximately 10 GHz) and a low AC current magnitude, such as applicable to RQL superconducting circuits. The first Josephson current source 352 includes a flux-shuttle loop 356 and a flux injector 358, and the second Josephson current source 354 includes a flux-shuttle loop 360 and a flux injector 362. Therefore, each of the first and second Josephson current sources 352 and 354 can be configured substantially similar to the Josephson current source 50 in the example of FIG. 2. Accordingly, each of the Josephson current sources 352 and 354 can be implemented to unidirectionally control the amplitude of the DC output current I_(DC). However, based on the arrangement of the first and second Josephson current sources 352 and 354 with respect to the output inductor L_(OUT), the first Josephson current source 352 can be configured to increase the amplitude of the DC output current I_(DC) and the second Josephson current source 354 can be configured to decrease the amplitude of the DC output current I_(DC), similar to as described previously in the example of FIG. 2.

In the example of FIG. 8, the Josephson current source system 350 also includes a controller 364 that is configured substantially similar to the controller 310 in the example of FIG. 7. The controller 364 includes a current register 366, a counter 368, a switch 370, a first RQL latch 372, and a second RQL latch 374, similar to as described previously in the example of FIG. 7. The current register 366 stores the value of the digital signal DC and provides the difference signal DIFF to the counter 368. Additionally, the current register 366 provides a switch signal SW to the switch 370 to select between enabling the first RQL latch 372 and the second RQL latch 374. For example, in response to the switch signal SW and the trigger signal TRG, the switch 370 can activate the flux-shuttle loop 356 via the flux injector 358 to increase the DC output current I_(DC) via the first input signal RQL_(IN1) provided as an SFQ pulse from the first RQL latch 372. Similarly, the switch 370 can deactivate the flux-shuttle loop 356 via the flux injector 358 to maintain the DC output current I_(DC) via the first input signal RQL_(IN1) provided as a reciprocal SFQ pulse from the first RQL latch 372. In addition, in response to the switch signal SW and the trigger signal TRG, the switch 370 can activate the flux-shuttle loop 360 via the flux injector 362 to decrease the DC output current I_(DC) via the second input signal RQL_(IN2) provided as an SFQ pulse from the second RQL latch 374. Similarly, the switch 370 can deactivate the flux-shuttle loop 360 via the flux injector 362 to maintain the DC output current I_(DC) via the second input signal RQL_(IN2) provided as a reciprocal SFQ pulse from the first RQL latch 372.

Accordingly, a pair of the Josephson current source circuits 50 implemented in the Josephson current source system 350 provides a programmable current source that allows full amplitude control of the DC output current I_(DC) by providing capability of both increasing and decreasing the amplitude of the DC output current I_(DC) using multiple flux-shuttle loops (e.g., a pair of flux shuttle loops 52) by selectively providing a fluxon to the respective flux-shuttle loops 52 to respectively increase and decrease the amplitude of the DC output current I_(DC), and an anti-fluxon to the flux-shuttle loop 52 to maintain the amplitude of the DC output current I_(DC). As a result, cross-talk between the separate flux injectors can be substantially mitigated.

As demonstrated in the examples of FIGS. 2 and 6, the in-phase clock signal AC_(I) and the quadrature-phase clock signal AC_(Q) are demonstrated as passing through the primary windings L₁ _(_) ₁, L₁ _(_) ₂, L₁ _(_) ₃, and L₁ _(_) ₄ of the transformers T₁, T₂, T₃, and T₄, respectively. However, the in-phase clock signal AC_(I) and the quadrature-phase clock signal AC_(Q) can, for example, be provided for a plurality of Josephson current sources, such as to generate a DC output current for a plurality of devices. FIG. 9 illustrates an example of a superconducting circuit system 400. As an example, the superconducting circuit system 400 can be implemented in any of a variety of quantum and classical computing applications, such as memory or processing systems. The superconducting circuit system 400 includes a plurality N of devices 402, where N is a positive integer. Each of the devices 402 receive a respective DC output current, demonstrated in the example of FIG. 9 as respective DC output currents I_(DC) _(_) ₁ through I_(DC) _(_) _(N) based on an AC input signal. As an example, the DC output currents I_(DC) _(_) ₁ through I_(DC) _(_) _(N) can be provided as power signals or as driver signals to drive the devices 402. For example, the devices 402 can each correspond to respective memory drivers, such as to provide read and write currents to an array of memory cells.

The superconducting circuit system 400 also includes a respective plurality of Josephson current sources 404 that are configured to generate the DC output currents I_(DC) _(_) ₁ through I_(DC) _(_) _(N). In the example of FIG. 9, the AC input signal is demonstrated as an in-phase clock signal AC_(I) and a quadrature-phase clock signal AC_(Q), such as demonstrated in the examples of FIGS. 2, 3, and 6. As an example, each of the Josephson current sources 404 can be configured substantially similar to the Josephson current source circuit 50 in the example of FIG. 2 or the Josephson current source circuit 250 in the example of FIG. 6, or as one of the Josephson current source systems 300 and 350 in the respective examples of FIGS. 7 and 8. Therefore, the Josephson current sources 404 can each include at least one flux-shuttle loop comprising four stages that are each configured substantially the same to propagate a fluxon around the loop to generate voltage pulses that are integrated into the respective DC output currents I_(DC) _(_) ₁ through I_(DC) _(_) _(N) via respective output inductors.

Each of the Josephson current sources 404 are also demonstrated as receiving at least one input signal RQL_(IN) _(_) ₁ through RQL_(IN) _(_) _(N) (e.g., with each including a first input signal RQL_(IN1) and a second input signal RQL_(IN2)) that can be provided to the Josephson current source 404 to control the operation of the Josephson current sources 404 to convert the in-phase clock signal AC_(I) and the quadrature-phase clock signal AC_(Q) to the DC output currents I_(DC) _(_) ₁ through I_(DC) _(_) _(N). Thus, each of the Josephson current sources 404 can be separately activated and deactivated, such that the Josephson current sources 404 can be independently controlled to provide separate amplitudes of the DC output currents I_(DC) _(_) ₁ through I_(DC) _(_) _(N). Additionally, while the Josephson current sources 404 are arranged in parallel in the example of FIG. 9, it is to be understood that the Josephson current sources 404 can instead be arranged in series, such as to collectively generate a single DC output current having a higher slew rate.

Similar to as described previously, the Josephson current sources 404 can therefore operate to generate the DC output currents I_(DC) _(_) ₁ through I_(DC) _(_) _(N) based on the in-phase clock signal AC_(I) and the quadrature-phase clock signal AC_(Q) in a power efficient manner and with independent control. The Josephson current sources 404 only dissipate power via the voltage pulses to provide the respective DC output currents I_(DC) _(_) ₁ through I_(DC) _(_) _(N) to the devices 402, such that no additional power is dissipated to maintain the fluxon propagating around the flux-shuttle loop in each of the Josephson current sources 404. In addition, the Josephson current sources 404 can generate substantially no heat from static power dissipation, as opposed to typical resistance-based DC power sources. Accordingly, the Josephson current sources 404 can operate efficiently and effectively in the superconducting circuit system 400.

In view of the foregoing structural and functional features described above, a methodology in accordance with various aspects of the present invention will be better appreciated with reference to FIG. 10. While, for purposes of simplicity of explanation, the methodology of FIG. 10 is shown and described as executing serially, it is to be understood and appreciated that the present invention is not limited by the illustrated order, as some aspects could, in accordance with the present invention, occur in different orders and/or concurrently with other aspects from that shown and described herein. Moreover, not all illustrated features may be required to implement a methodology in accordance with an aspect of the present invention.

FIG. 10 illustrates an example of a method 450 for controlling an amplitude of a DC output current (e.g., the DC output current I_(DC)). At 452, a first SFQ pulse (e.g., via the input signal RQL_(IN) ) is provided to a first flux injector (e.g., one of the flux injectors 306 and 358) to generate a first fluxon that propagates around at least one flux-shuttle loop (e.g., the flux shuttle loop 252 or the flux shuttle loop 52) via sequential triggering of a plurality of Josephson junctions (e.g., the Josephson junctions J₁ _(_) ₁, J₂ _(_) ₁, J₁ _(_) ₂, J₂ _(_) ₂, J₁ _(_) ₃, J₂ _(_) ₃, J₁ _(_) ₄, and J₂ _(_) ₄) based on an AC input signal (e.g., the clock signal AC) to increase the amplitude of the DC output current in an output inductor (e.g., the output inductor L_(OUT)). At 454, a first reciprocal SFQ pulse is provided (e.g., via the input signal RQL_(IN)) to the first flux injector to generate a first anti-fluxon that substantially cancels the first fluxon to maintain the amplitude of the DC output current. At 456, a second SFQ pulse is provided (e.g., via the input signal RQL_(IN)) to a second flux injector (e.g., one of the flux injectors 308 and 362) to generate a second fluxon that propagates around the at least one flux-shuttle loop via sequential triggering of the plurality of Josephson junctions based on the AC input signal to decrease the amplitude of the DC output current in the output inductor. At 458, a second reciprocal SFQ pulse is provided (e.g., via the input signal RQL_(IN)) to the second flux injector to generate a second anti-fluxon that substantially cancels the second fluxon to maintain the amplitude of the DC output current.

What have been described above are examples of the invention. It is, of course, not possible to describe every conceivable combination of components or methodologies for purposes of describing the invention, but one of ordinary skill in the art will recognize that many further combinations and permutations of the invention are possible. Accordingly, the invention is intended to embrace all such alterations, modifications, and variations that fall within the scope of this application, including the appended claims. 

What is claimed is:
 1. A Josephson current source system comprising: a flux-shuttle loop comprising a plurality of Josephson junctions spaced about the flux-shuttle loop and being configured, when activated, to sequentially trigger the plurality of Josephson junctions about the flux-shuttle loop, in response to an inductively-coupled AC input signal, to generate a DC output current provided through an output inductor; and a flux injector that is configured to selectively activate and deactivate the flux-shuttle loop to control an amplitude of the DC output current.
 2. The system of claim 1, wherein the flux injector is configured to activate the flux-shuttle loop to initiate sequential triggering of the plurality of Josephson junctions about the flux-shuttle loop in response to a single-flux quantum (SFQ) pulse, and is configured to deactivate the flux-shuttle loop in response to a reciprocal SFQ pulse.
 3. The system of claim 1, wherein flux-shuttle loop comprises a superconducting quantum interference device (SQUID) comprising a flux state corresponding to one of activation and deactivation of the flux-shuttle loop, and wherein the flux injector is configured to change the flux state in response to an input signal to one of activate and deactivate the flux-shuttle loop.
 4. The system of claim 3, wherein the SQUID comprises a SQUID Josephson junction that forms part of the flux-shuttle loop, and wherein the flux injector further comprises a transformer comprising a first inductor configured to propagate a DC bias current, a second inductor that is magnetically coupled with the first inductor and is configured to propagate the input signal, and a third inductor that is magnetically coupled with the first and second inductors and which forms part of the SQUID, such that the SQUID Josephson junction triggers in response to the input signal to activate and deactivate the flux-shuttle loop.
 5. The system of claim 4, wherein the flux-shuttle loop comprises a plurality of stages that are each associated with a respective phase of the AC input signal, wherein each of the plurality of stages comprises a storage inductor interconnecting the respective one of the plurality of stages with the output inductor and being configured to provide a voltage pulse to the output inductor to increase the DC output current in response to the sequential triggering of the plurality of Josephson junctions, wherein one of the plurality of stages comprises the flux injector, such that the third inductor is configured as the storage inductor associated with the respective one of the plurality of stages.
 6. The system of claim 1, wherein the AC input signal comprises an in-phase AC input signal and a quadrature-phase AC input signal.
 7. The system of claim 6, wherein the flux-shuttle loop further comprises a plurality of transformers configured to inductively couple the flux-shuttle loop with each of the in-phase AC input signal and the quadrature-phase AC input signal, wherein the in-phase AC input signal is provided through a primary winding of a first portion of the plurality of transformers to induce a bias current in a secondary winding of the first portion of the plurality of transformers, and wherein the quadrature-phase AC input signal is provided through a primary winding of a second portion of the plurality of transformers to induce a bias current in a secondary winding of the second portion of the plurality of transformers to facilitate the sequential triggering of the plurality of Josephson junctions.
 8. The system of claim 1, wherein the flux-shuttle loop comprises a plurality of stages, wherein the flux injector is configured as one of the plurality of stages, each of the plurality of stages comprising: a transformer configured to generate a bias current based on inductive coupling of the AC input signal; a Josephson junction configured to trigger to generate a voltage pulse in response to the bias current; and a storage inductor interconnecting the respective one of the plurality of stages with the output inductor and being configured to provide the voltage pulse to the output inductor.
 9. The system of claim 1, wherein the flux injector is a first flux injector that is configured to selectively activate and deactivate the flux-shuttle loop in response to a first input signal to selectively increase the amplitude of the DC output current based on sequential triggering of the plurality of Josephson junctions about the flux-shuttle loop when the flux-shuttle loop is activated by the first flux injector, the system further comprising a second flux injector that is configured to selectively activate and deactivate the flux-shuttle loop in response to a second input signal to selectively decrease the amplitude of the DC output current based on sequential triggering of the plurality of Josephson junctions about the flux-shuttle loop when the flux-shuttle loop is activated by the second flux injector.
 10. A superconducting current source comprising the Josephson current source system of claim 1, wherein the Josephson current source system is configured to increase the amplitude of the DC output current in response to activation of the flux-shuttle loop, the superconducting current source further comprising: a controller configured to set the amplitude of the DC output current in response to a programmable current register and to generate a first input signal and a second input signal, the first input signal being provided to the flux injector to activate the flux-shuttle loop; and a second Josephson current source system comprising: a second flux-shuttle loop comprising a second plurality of Josephson junctions spaced about the second flux-shuttle loop and being configured, when activated, to sequentially trigger the second plurality of Josephson junctions about the second flux-shuttle loop in response to the inductively-coupled AC input signal to decrease the DC output current provided through the output inductor; and a second flux injector that is configured to selectively activate and deactivate the second flux-shuttle loop in response to the second input signal.
 11. A superconducting circuit system comprising a plurality of the Josephson current source system of claim 1, the plurality of Josephson current source systems being configured to generate a respective plurality of DC output currents.
 12. A method for controlling an amplitude of a DC output current, the method comprising: providing a first single-flux quantum (SFQ) pulse to a first flux injector to generate a first fluxon element that propagates around at least one flux-shuttle loop via sequential triggering of a plurality of Josephson junctions based on an AC input signal to increase the amplitude of the DC output current in an output inductor; providing a first reciprocal SFQ pulse to the first flux injector to generate a first anti-fluxon element that substantially cancels the first fluxon element to maintain the amplitude of the DC output current; providing a second SFQ pulse to a second flux injector to generate a second fluxon element that propagates around the at least one flux-shuttle loop via sequential triggering of the plurality of Josephson junctions based on the AC input signal to decrease the amplitude of the DC output current in the output inductor; and providing a second reciprocal SFQ pulse to the second flux injector to generate a second anti-fluxon element that substantially cancels the second fluxon element to maintain the amplitude of the DC output current.
 13. The method of claim 12, further comprising: receiving a digital signal corresponding to a desired amplitude of the DC output current; providing one of the first SFQ pulse and the second SFQ pulse to generate the respective one of the first fluxon element and the second fluxon element to one of increase and decrease the amplitude of the DC output current, respectively; counting periods of the AC input signal, each period of the AC input signal corresponding to an increment of the amplitude of the DC output current; and providing one of the first reciprocal SFQ pulse and the second reciprocal SFQ pulse to generate the respective one of the first anti-fluxon element and the second anti-fluxon element to maintain the amplitude of the DC output current in response to a quantity of periods of the AC input signal being sufficient for the DC output current to be approximately equal to the desired amplitude of the DC output current.
 14. The method of claim 12, wherein providing the first SFQ pulse comprises providing the first SFQ pulse to the first flux injector to generate the first fluxon element as a fluxon that propagates around a flux-shuttle loop, and wherein providing the second SFQ pulse comprises providing the second SFQ pulse to the second flux injector to generate the second fluxon element as an anti-fluxon that propagates around the flux-shuttle loop.
 15. The method of claim 12, wherein providing the first SFQ pulse comprises providing the first SFQ pulse to the first flux injector to generate the first fluxon element as a fluxon that propagates around a first flux-shuttle loop, and wherein providing the second SFQ pulse comprises providing the second SFQ pulse to the second flux injector to generate the second fluxon element as a fluxon that propagates around a second flux-shuttle loop, wherein the first and second flux-shuttle loops are coupled to the output inductor on opposite ends of the output inductor.
 16. A Josephson current source system comprising: a flux-shuttle loop comprising a plurality of Josephson junctions spaced about the flux-shuttle loop and being configured, when activated, to sequentially trigger the plurality of Josephson junctions about the flux-shuttle loop in response to an inductively-coupled AC input signal to generate a DC output current provided through an output inductor; and a flux injector comprising a superconducting quantum interference device (SQUID) having one of a first flux state and a second flux state, the flux injector being configured to change from the first flux state to the second flux state in response to a single-flux quantum (SFQ) pulse to activate the flux-shuttle loop to increase an amplitude of the DC output current, the flux injector being further configured to change from the second flux state to the first flux state in response to a reciprocal SFQ pulse to deactivate the flux-shuttle loop to maintain the amplitude of the DC output current.
 17. The system of claim 16, wherein the SQUID comprises a SQUID Josephson junction that forms part of the flux-shuttle loop, and wherein the flux injector further comprises a transformer comprising a first inductor configured to propagate a DC bias current, a second inductor that is magnetically coupled with the first inductor and is configured to propagate the SFQ pulse and the reciprocal SFQ pulse, and a third inductor that is magnetically coupled with the first and second inductors and which forms part of the SQUID, such that the SQUID Josephson junction triggers in response to the SFQ pulse and the reciprocal SFQ pulse to activate and deactivate the flux-shuttle loop, respectively.
 18. The system of claim 17, wherein the flux-shuttle loop comprises a plurality of stages that are each associated with a respective phase of the AC input signal, wherein each of the plurality of stages comprises a storage inductor interconnecting the respective one of the plurality of stages with the output inductor and being configured to provide a current increment to the output inductor to increase the DC output current in response to the sequential triggering of the plurality of Josephson junctions, wherein one of the plurality of stages comprises the flux injector, such that the third inductor is configured as the storage inductor associated with the respective one of the plurality of stages.
 19. The system of claim 16, wherein the flux injector is a first flux injector that is configured to selectively activate and deactivate the flux-shuttle loop in response to a first SFQ pulse and a first reciprocal SFQ pulse, respectively, to selectively increase the amplitude of the DC output current based on sequential triggering of the plurality of Josephson junctions about the flux-shuttle loop when the flux-shuttle loop is activated by the first flux injector, the system further comprising a second flux injector that is configured to selectively activate and deactivate the flux-shuttle loop in response to a second SFQ pulse and a second reciprocal SFQ pulse, respectively, to selectively decrease the amplitude of the DC output current based on sequential triggering of the plurality of Josephson junctions about the flux-shuttle loop when the flux-shuttle loop is activated by the second flux injector.
 20. A superconducting current source comprising the Josephson current source system of claim 16, wherein the Josephson current source system is configured to increase the amplitude of the DC output current in response to activation of the flux-shuttle loop, the superconducting current source further comprising: a controller configured to set the amplitude of the DC output current in response to a programmable current register and to generate a first SFQ pulse and a first reciprocal SFQ pulse associated with the Josephson current source system and a second SFQ pulse and a second reciprocal SFQ pulse; and a second Josephson current source system comprising: a second flux-shuttle loop that is inductively coupled with the AC input signal, the second flux-shuttle loop comprising a second plurality of Josephson junctions spaced about the second flux-shuttle loop and being configured, when activated, to sequentially trigger the second plurality of Josephson junctions about the second flux-shuttle loop in response to the AC input signal to decrease the DC output current provided through the output inductor; and a second flux injector comprising a second SQUID and which is configured to selectively activate and deactivate the second flux-shuttle loop in response to the second SFQ pulse and the second reciprocal SFQ pulse. 